DE10154277A1 - Light acquiring device used in an electronic device comprises a light sensor having a receiving section for receiving light produced by a light source, and an infrared barrier filter element - Google Patents

Abstract

Light acquiring device comprises a light sensor (KA) having a receiving section (AA) for receiving light produced by a light source; and an infrared barrier filter element (IRSG) arranged between the receiving section of the light sensor and the light source to prevent light contacting the receiving section in the infrared region.

Description

The present invention relates to a Light detection device with an infrared cut filter, as well an electronic device in which such Light detection device is provided.

Light sensors in the design of a photo transistor or as an imaging element, such as a CCD (Charge Coupled Device = charge coupled device) camera element, are in the essential. Silicon and polysilicon manufactured and have the property that they are not only visible Spectrum, but also in the infrared range up to 1200 nanometers are sensitive. That means that without a special Filtering or without blocking the infrared light from this the light sensor detects infrared light at Color imaging leads to poor color reproduction. This results in a with different lighting conditions different color reproduction of the sensor, although that human eye perceives the same color. In particular with artificial light, such as that in a Halogen lamp or a tungsten wire lamp in which light components have a high intensity in the infrared spectral range, the color reproduction of a light sensor differs or a camera element significantly different from that in daylight. For this reason, it is necessary to use an infrared cut filter for an optimal optical performance of a To use light sensor or a camera element. This Infrared cut filter traditionally consists of a thin glass, which is provided with an infrared cut filter coating. However, this prior art infrared cut filter has several disadvantages. For one, it provides an additional one Component, it is very expensive to manufacture, and it requires one due to its low mechanical stability high technical effort, this in a photo camera or use a video camera, etc.

It is therefore the object of the present invention, a Light detection device with an infrared cut filter create that with low procedural and device-technical effort can be produced.

This task is accomplished by a light detection device according to claim 1 and by an electronic device solved according to claim 9. Advantageous embodiments of the Invention are the subject of the dependent claims.

A light detection device according to the invention has a light sensor, which has a receiving section for Receiving light emitted by a light source having. A CCD (CCD: Charge Coupled Device = Charge Coupled Device) camera element, a CMOS (CMOS: Complementary Metal Oxide Semiconductor Complementary metal oxide semiconductor) camera element, a Photo transistor, etc. can be used. The The light detection device further includes one made of a plastic Infrared cut filter element that between the Receiving section of the light sensor and the light source is arranged, to prevent infrared light from reaching the Recording section of the light sensor hits. Training the Conditional infrared cut filter made of plastic a higher mechanical stability in contrast to the Execution of a fragile glass support with a Infrared blocking filter coating in the prior art. Consequently the process and device technology is reduced Effort when providing or installing the filter in the Light detection device because there are no special ones Precision tools are required when installing the filter. by virtue of which also reduce the manufacturing costs of light detection device according to the invention.

According to an advantageous embodiment of the invention the light detection device one or more optical Assemblies for breaking or guiding the from the light source have emitted light. An optical assembly can a lens for refracting light or a light guide for guiding light. It is special advantageous if the infrared cut filter element as the optical assembly, such as a lens or a light guide, is formed or at least partially as the optical Module is formed or is integrated in this. A such a construction in which the infrared cut filter element has a double optical functionality several advantages. First, there is only one component, i.e. H. the double optically effective infrared cut filter element, to manufacture and is later only this one part in one Install light detection device. This therefore reduces the Complexity of the construction and also the manufacturing or Assembly costs. On the other hand, the stability of the Infrared cut filter element and thus that of the whole Light detection device increased. Will with a conventional Structure of the light detection device, in particular in the Use with a light guide element that Light guide element formed from a coated glass Infrared cut filter and the light sensor as close as possible to each other arranged to have good light transmission between the To ensure components, the problem arises here that especially when the Light detection device of the light guide touch the infrared cut filter and can damage. However, the infrared cut filter immediately integrated in the light guide or as this trained, such damage can be avoided.

In addition to the possibility of the infrared cut filter element as a To form a double optically effective element, it is according to a further advantageous embodiment also possible the infrared cut filter element as a mechanically effective Form element of the light detection device. It is it is possible for the light detection device to have a housing in which the light sensor and possibly one of the above mentioned optical modules are housed. It is possible that the entire housing of the Light detection device or only part of the housing, such as a cover for admitting light, made of plastic. Infrared cut filter element are formed. It is there also possible on the housing cover, which also as Protective glass can be called an optically imaging element, like a lens to provide or shape so that the Covering both a mechanical task of protecting mechanical impact and sealing against Foreign matter and two optical tasks, namely the breaking of Has light and blocking infrared radiation. Further it is possible to use the light sensor, especially in the Embodiment of a CCD chip to be provided in a housing that is made of the infrared cut filter made of plastic is made. In the case of CCD chips, for example, surface-mountable components are designed to by means predetermined solder pins on the surface of a circuit board to be attached, the housing around the light sensor or CCD chip by injection molding the plastic Infrared cut filters are manufactured. It is also conceivable the light sensor using other methods of molding Pack plastic in a plastic case. It is here again noted that by using the Technically, infrared cut filters made of a plastic material sophisticated and easy-to-use processes for shaping the Infrared cut filter element and thus for merging or Integration with a light sensor are available. In particular, packing the light sensor or a CCD chip An infrared cut filter housing causes only a single one Component, namely the packed light sensor, is created is easy to handle, and thus particularly in the Execution of a surface-mountable component easily on a PCB is mountable. It also creates a stable one Component, because the light sensor through the plastic housing the infrared cut filter element is mechanically protected.

The infrared cut filter element made of plastic can as a mechanically effective carrier element or Carrier matrix a thermoplastic, such as acrylic glass (PMMA) or polycarbonate (PC), which is transparent and in particular is mechanically stable. To achieve the The functionality of an infrared cut filter can do that Plastic-formed infrared cut filter element pigments have that absorb light in the infrared spectral range and preferably in the infrared cut filter element or whose carrier matrix are provided. Such a material or such a plastic for a Infrared blocking filter element is, for example, under the name "HESA® glass" from distributed by "Notz Plastics AG" in Switzerland. It it is also conceivable that the plastic Infrared blocking filter element a coating, in particular a Plastic coating, which is used for mechanical Stabilization of the surface of the filter element or Improvement of the scratch resistance is provided and / or for optical effectiveness in the infrared spectral range can include absorbent pigments. Such a coating is, for example, under the name "infradur PLUS" by the Company "UVEX. ARBEITSSCHUTZ GMBH" distributed in Germany.

According to another aspect of the present invention an electronic device with a Light detection device created as described above.

According to an advantageous embodiment of the electronic This device has an electronic display with a Lighting element for providing the display with light certain lighting intensity. Furthermore, the electronic device a lighting control device, the one with the electronic display and the light sensor the light detection device is connected to the Illumination intensity of the lighting element depending on the Intensity of the light that hits the light sensor increases Taxes. This configuration of the electronic device thus creates the possibility of reducing the power consumption at the Illumination of the display to the ambient light conditions of the adapt electronic device, and in particular at high intensity of ambient light Illumination intensity of the lighting element to decrease on this Way to save electricity. Especially with electronic ones Devices that use colored displays is the Power consumption about ten times higher than that of single color or monochrome displays. It is therefore advantageous to Reduction of the power consumption or the power consumption of the electronic device an inventive Light detection device in connection with a Lighting control device to use to the ambient light of the electronic device to detect, and depending on it Intensity the illuminance or illuminance one or more lighting elements of the (colored) Control display. In particular through the use of the Infrared cut filter in the invention Light detection device allows the light detection of the Light sensor and therefore not the lighting control is affected if the sensor is in the infrared range is sensitive. In this way, lighting control of the Lighting element of the display under different Lighting conditions, be it daylight or artificial light, guaranteed.

The electronic device can be used as a mobile radio device, like a cell phone or a cordless phone, as a portable computer, camera or video camera, etc. be trained. In particular, the mobile device can the UMTS (Universal Mobile Telecommunication Service) standard work.

Preferred embodiments of the present invention are made below with reference to the accompanying drawings explained in more detail. Show it

Figure 1 is a schematic representation of a light detection device according to the invention according to a first embodiment, in which an infrared cut filter element is designed in the form of a protective glass.

Fig. 2 is a schematic representation of a light detection apparatus according to a second embodiment in which the infrared cutoff filter element in the form of a lens is formed;

Fig. 3 is a schematic representation of the light detecting device according to the invention according to a third embodiment in which the infrared cutoff filter element in the form of an optical waveguide is formed;

Fig. 4 is a schematic diagram of the light detection apparatus according to the invention according to a fourth embodiment in which the infrared cutoff filter element is designed as a display cover;

Fig. 5 is a schematic representation of the light detection device according to the invention according to a fifth embodiment, in which the infrared cut filter element is designed as an injection molded plastic housing.

Fig. 1 now shows a cross-sectional view of a light detecting apparatus according to a first embodiment in the form of a camera module KM1. Such a camera module can be used, for example, in digital cameras or video cameras, but also in mobile radio devices. Depending on the design of the light sensor, either individual images or video sequences can be recorded.

When viewed from the outside in, the KM1 camera module points two housing walls G1 and G2 on which different Carrier elements for carrying the for the operation of the camera module KM1 necessary components are attached. This Carrier elements comprise a first and a second camera carrier element TK1 and TK2 for carrying a substrate SU on which a electronic camera element KA or several electronic Camera elements KA are applied. It should be noted that in the following description for better understanding only one camera element KA is spoken of. The Camera element can be used as a CCD camera element, as a CMOS Camera element, etc. be formed. On an upper one Section, the camera element KA has a receiving section AA to record light from the top of the camera module incident. To control the camera element KA or Processing of the image signals generated by the camera element KA electrical lines KL are provided which provide a connection from the camera element KA to one Manufacture control / processing device (nothing shown). To the Housing walls G1 and G2 are also lower lens support elements TLU1 and TLU2 and upper lens support elements TLO1 and TLO2 for Wear or hold a lens L attached. The lens serves thereby as an optical assembly and in particular as one optical imaging element. It is conceivable instead of Lens L used to refract light, other optical To use assemblies, such as a mirror for Reflecting light or a light guide (for example made of glass fiber) for guiding or redirecting light. It is also conceivable to a plurality of optical assemblies use. A plurality of the same optical Assemblies like lenses can be "interconnected", or it can complex optical systems from different optical Assemblies are created.

Finally, on the housing walls G1 and G2 are first and second protective glass support TS1 and TS2 attached, one of which Protective glass or a transparent fabric in general shockproof mechanical properties is worn. Moreover The protective glass is intended to serve the interior of the camera module to seal against foreign substances from the environment. According to In the first embodiment, the protective glass IRSG is made of one Plastic formed, the functionality of a Has infrared cut filter element. This plastic can too be an acrylic glass as in the following embodiments, in which pigments are provided, the light in the infrared range absorb. The infrared cut filter element is thus in the Location, infrared light for example with a wavelength in the To prevent a range of approximately ≥ 800 nanometers from occurring to penetrate the filter element. By locking the Light in the infrared range on which the camera element would normally be sensitive, it is possible that in the Camera element even under different lighting conditions, be it natural daylight or artificial light, one Color reproduction similar to that of the human eye, which can only be seen in the visible spectral range is sensitive.

Due to the formation of the protective glass as an infrared Filter element, the protective glass has a double function, on the one hand, it serves as a mechanically effective element and on the other hand as an optically effective element in the function an infrared cut filter element. Thus a additional separate filter element made of glass, as in the state of the Technique used to be omitted. This diminishes both the manufacturing cost of the components and the cost when assembling the camera module KM1. It is also through omitting an easily breakable glass filter like the one he had used in the prior art, the stability of the Camera module KM1 improved.

In FIG. 2, a second embodiment in the inventive light detecting device of a camera module KM2 is shown. The structure of the camera module KM2 of the second embodiment essentially corresponds to the structure of the camera module KM1 of the first embodiment, which is why a detailed description of the components common to both embodiments is omitted below. The characteristic of the camera module KM2 of the second embodiment is that it is not the protective glass SG but the optical assembly, namely the lens IRL, that is made of a plastic that serves as an infrared cut filter element. As already mentioned, it is conceivable to provide further optical assemblies, such as further lenses or light guides, instead of or in addition to the lens IRL. These further optically active elements can also be produced from a plastic which has the functionality of an infrared cut filter element.

It is also conceivable to remove the protective glass SG especially if there is a good or adequate seal between the Support elements TLO1, TLO2, TLU1, TLU2 and the lens IRL manufactured or a careful and. prudent of Camera module can be required. However, it is also conceivable the protective glass IRSG of the first embodiment in the form of a Plastic blocking filter element made of plastic to manufacture and, for example, at the light sensor facing side to form a lens section in the protective glass. In the simplest case, this can be an additional lens to be omitted, which also includes building components and costs minimized.

In Fig. 3 shows a third embodiment of the light detecting device according to the invention, there is shown a light detection module which is installed in a mobile device MP for detecting the light intensity of the ambient light. More specifically, the view shown in FIG. 3 is a cross-sectional view of part of the mobile device. The mobile radio device MP has an upper housing element or an upper cover OGE and a lower housing element or a lower cover UGE. In the housing there is a printed circuit board LP on which, in addition to electronic modules for establishing a communication connection, for processing control instructions, etc., a light sensor LS is also provided, for example in the form of a phototransistor. The light detection principle of the phototransistor, which is in particular made of silicon, consists in the fact that the resistance of the collector-emitter path of the transistor changes depending on the incidence of light on the base. This means that the higher the intensity of the light incident on the base, the lower the collector-emitter resistance, and the higher the collector current. Such a change in the collector-emitter resistance can be recorded electronically in order to draw conclusions about the intensity of the light that falls on the phototransistor. The light sensor LS is surrounded by a housing, which is represented in the figure by the housing walls G1 and G2: In order to guide light from the surroundings of the mobile radio device MP to the light sensor LS arranged on the printed circuit board LP, a light guide IRLL is provided, which starts from the upper housing element OGE is led to the light sensor LS or to a light receiving section thereof. This light guide IRLL is made of a plastic that has the functionality of an infrared cut filter element.

As already mentioned, the light sensor LS is particularly in the execution of a photo transistor, conventionally in essentially made of silicon. This causes one Sensitivity of the sensor not only in the visible spectrum, but also in the infrared range up to 1200 nanometers. by virtue of this fact makes the light sensor among different Light conditions, be it natural daylight or artificial light, different brightness values or Detect intensity values of the light around the mobile phone MP. For this reason, the IRLL light guide is made of one Plastic provided the functionality of a Has infrared cut filter. This enables the Light sensor LS detects light in the visible Spectral range, similar to the human eye, which is why a Use of such a light sensor in connection with a Infrared cut filter also for lighting control of a Display is usable, as in the next embodiment will be described. The light sensor LS, the housing walls G1 and G2 as well as the light guide IRLL can also be used as LEM light detection module.

In FIG. 4 is a cross sectional view of a light detection apparatus according to the invention, there is shown according to a fourth embodiment in the form of a light detection module which is housed in a mobile device MP. More specifically, Fig. 4 shows the cross-sectional view of only a portion of the mobile device MP, namely the part in which a display is provided. Similar to the illustration in FIG. 3, the mobile radio device MP has a lower housing element UGE and an upper housing element OGE, in which a printed circuit board LP is provided (whereby, as in FIG. 3, the transition from the upper to the lower one occurs below the printed circuit board LP lower housing element). In addition to other electronic devices (not shown), a display module AZ is provided on the printed circuit board LP, which has a light sensor LS for detecting the light intensity of the ambient light of the mobile radio device MP. The upper housing element OGE also has a display cover IRAD made of plastic, which is arranged above the display module AZ and is designed as an infrared cut filter element, ie in order to transmit light in the visible spectrum and to block light in the infrared range. The light sensor LS and the cover IRAD can be referred to as the light detection module LEM, in contrast to the embodiment shown in FIG. 3 the light sensor being integrated in the display module.

The display module AZ can, for example, be a Liquid crystal display (LCD: Liquid Cristal Display), especially with a Color representation, have a Lighting element, such as an LED (LED: light emitting diode = light-emitting diode or light-emitting diode) to provide the display with Includes light of a certain lighting intensity. The Light sensor LS and the display module AZ are with one Lighting control device (not shown) connected, which is designed to control the lighting intensity of the Lighting element depending on the intensity of the light, that on the light sensor or on its Light receiving section hits to control. That means the light sensor LS detects light from the environment of the mobile radio MP hits the light sensor through the display cover IRAD and gives an intensity signal to the Lighting control device. The lighting control device can Have a table or figure stored in them that indicates what lighting intensity the lighting element of the Display module depending on the light sensor LS should have detected light intensity. Using this table or figure determines the lighting control device then the value of the lighting intensity of the Lighting element and gives a corresponding signal to the display module AZ off.

Such a lighting control, on the one hand ensures that a user of the mobile device MP always a clear and bright display on his mobile device MP receives and that the lighting intensity of the Lighting element is adapted to the ambient light. Thus at high ambient light intensity, as on a sunny Summer day prevails, the lighting intensity of the Lighting element be low, whereas at night the Illumination intensity of the lighting element will be increased. On this way the energy consumption or electricity consumption of the Display module to the current ones Adapted to ambient lighting conditions, thereby saving energy and thus the lifespan of the mobile device without a corresponding one Charging the battery is improved. Training the Display cover IRAD made of plastic with functionality an infrared cut filter in turn enables the Light sensor LS has a light sensitivity similar to that of one human eye so that the Lighting control device also in the case of different lighting conditions Is capable of a tax transaction according to needs of a human eye.

Again, it should be noted that the display cover IRAD again fulfills a double function, namely the one a mechanically active element in the form of a Protective glass and on the other hand that of an optically effective element in the execution of an infrared cut filter element.

The display module AZ can be in addition to or instead of Liquid crystal display other (also colored) display components, like an OLED (OLED: organic light emitting diode = organic light-emitting diode or organic light-emitting diode) etc. have.

Fig. 5 shows a cross-sectional view of a light detecting device of the invention according to a fifth embodiment in the form of a packed camera element. More specifically, a camera element KA has a carrier substrate, on which a CCD array or CCD field for capturing or recording image information is applied. The camera element KA is surrounded by a plastic housing IRPA, which has been formed around the camera element KA for example by means of casting or injection molding or another plastic molding process. The plastic housing IRPA is made of a transparent plastic that has the functionality of an infrared cut filter. Furthermore, the camera element KA has solder pins SP1 and SP2, which are provided to create an electrical connection with the camera element KA from the outside of the housing IRPA. As can be seen from FIG. 5, the solder pins SP1 and SP2 are provided in such a way that the camera element together with the housing can be electrically connected by means of surface mounting on a printed circuit board.

The housing IRPA thus in turn serves as a mechanically active element for protecting the camera element from external influences and for preventing infrared components from light from striking a receiving section AA of the camera element KA. This fifth embodiment again causes an additional infrared cut-off filter made of glass, as is used in the prior art, to be omitted, which on the one hand again reduces the cost of the light detection device and increases the stability of the device. Reference numeral list AA receiving section
AZ display module from MP
G1, G2 First and second housing wall of KM1 and KM2
IRAD display cover with infrared cut filter made of plastic
IRL lens with infrared cut filter made of plastic
IRLL light guide with infrared cut filter made of plastic
IRPA injection molded plastic housing with infrared cut filter
IRSG protective glass made of infrared cut filter made of plastic
KA electronic camera element
KL Electrical line from KA to control KA and to forward / process image information from KA
KM1, KM2 camera module of the first and second embodiment
L lens
LEM light detection module
LP circuit board from MP
LS light sensor
MP mobile device
OGE Upper housing element
SG protective glass
SP1, SP2 solder pins
SU substrate for wearing KA
TK1, TK2 camera support elements
TLO1, TLO2 Upper lens support elements
TLU1, TLU2 Lower lens support elements
TS1, TS2 protective glass support elements
UGE lower housing element

Claims (12)

1. Light detection device with the following features:
a light sensor (LS; KA) having a receiving section (AA) for receiving light emitted from a light source;
an infrared blocking filter element (IRSG; IRL; IRLL; IRAD; IRPA) made of a plastic, which is arranged between the receiving section of the light sensor (LS; KA) and the light source in order to prevent light in the infrared region from being incident on the receiving section (AA) of the Light sensor hits. 2. Light detection device according to claim 1, wherein the Infrared blocking filter element (IRL; IRLL) as an optical Assembly for breaking (IRL) or guiding (IRLL) of the Light source emitted light is formed. 3. Light detection device according to claim 2, wherein the optical assembly a lens (IRL) or a light guide (IRLL) is. 4. Light detection device according to claim 1, wherein the Infrared blocking filter element (IRSG; IRAD; IRPA) as one mechanically effective element of the light detection device is trained. 5. Light detection device according to claim 2, wherein the mechanically effective element a cover (IRSG; IRAD) the Light detection device or a housing of the Light detection device or a housing of the light sensor (IRPA) is. 6. Light detection device according to one of claims 1 to 5, where the light sensor (LS; KA) is a CCD camera or comprises a CMOS camera or a phototransistor. 7. Light detection device according to one of claims 1 to 6, in which the formed from a plastic Infrared cut filter element a thermoplastic, such as Has acrylic glass or polycarbonate. 8. Light detection device according to one of claims 1 to 7, in which the plastic-formed Infrared blocking filter element has pigments that light in the infrared Absorb spectral range. 9. Electronic device with one Light detection device according to one of claims 1 to 8. 10. The electronic device of claim 9, further comprising:
an electronic display (AZ) with a lighting element for providing the display with light of a specific lighting intensity;
a lighting control device which is connected to the electronic display (AZ) and to the light sensor (LS) of the light detection device (LEM) in order to control the lighting intensity of the lighting element in dependence on the intensity of the light which strikes the light sensor. 11. The electronic device of claim 10, wherein the Lighting control device, the lighting intensity of the The higher the lighting element, the more it diminishes Intensity of the light striking the light sensor. 12. Electronic device according to one of claims 9 to 11, which as a mobile device, a portable computer, a Camera or a video camera is formed.